Permutations and Combinations

Practice A Permutations and Combinations Express each expression as a product of factors. 1. 6! 2. 3! 3. 7! 4. 8! 5! 5. 4! 2! 6. 9! 6! Evaluate each expression. 7. 5! 8. 9! 9. 3! 10. 8! 11. 7! 4! 12. 8! 7! 13. 5! 2! 14. 7! 5! 15. (6 3)! 16. 4! (6 2)! 17. 9! (8 3)! 18. 7! (9 4)! 19. An anagram is a rearrangement of the letters of a word or words to make other words. How many possible arrangements of the letters W, O, R, D, and S can be made? 20. Janell is having a group of friends over for dinner and is setting the name cards on the table. She has invited 5 of her friends for dinner. How many different seating arrangements are possible for Janell and her friends at the table? 21. How many different selections of 4 books can be made from a bookcase displaying 12 books?

Practice B Permutations and Combinations Evaluate each expression. 1. 10! 2. 13! 3. 11! 8! 4. 12! 9! 5. 15! 8! 6. 18! 12! 7. 13! (17 12)! 8. 19! (15 2)! 9. 15! (18 10)! 10. Signaling is a means of communication through signals or objects. During the time of the American Revolution, the colonists used combinations of a barrel, basket, and a flag placed in different positions atop a post. How many different signals could be sent by using 3 flags, one above the other on a pole, if 8 different flags were available? 11. From a class of 25 students, how many different ways can 4 students be selected to serve in a mock trial as the judge, defending attorney, prosecuting attorney, and the defendant? 12. How many different 4 people committees can be formed from a group of 15 people? 13. The girls basketball team has 12 players. If the coach chooses 5 girls to play at a time, how many different teams can be formed? 14. A photographer has 50 pictures to be placed in an album. How many combinations will the photographer have to choose from if there will be 6 pictures placed on the first page?

Practice C Permutations and Combinations Evaluate each expression. 1. 16! (15 4)! 2. 21! (19 3)! 3. 17! 5!(17 5)! 4. 7 P 3 5. 9 P 4 6. 10 P 8 7. 18 P 2 8. 9 C 2 9. 11 C 5 10. 13 C 11 11. 15 C 3 12. The music class has 20 students and the teacher wants them to practice in groups of 5. How many different ways can the first group of 5 be chosen? 13. Math, science, English, history, health, and physical education are the subjects on Jamar s schedule for next year. Each subject is taught in each of the 6 periods of the day. From how many different schedules will Jamar be able to choose? 14. The Hamburger Trolley has 25 different toppings available for their hamburgers. They have a $3 special that is a hamburger with your choice of 5 different toppings. Assume no toppings are used more than once. How many different choices are available for the special? 15. Many over the counter stocks are traded through Nasdaq, an acronym for the National Association of Securities Dealers Automatic Quotations. Most of the stocks listed on the Nasdaq use a 4-digit alphabetical code. For example, the code for Microsoft is MSFT. How many different 4-digit alphabetical codes could be available for use by the association? Assume letters cannot be reused.

Review for Mastery Permutations and Combinations Factorial: a string of factors that counts down to 1 6! = 6 5 4 3 2 1 To evaluate an expression with 5! 5 4 3 2 1 = = 5 4 = 20 factorials, cancel common factors. 3! 3 2 1 Complete to evaluate each expression. 1. 7! 7 6 5 6! 6! = 2. = = 4! (5 2)!! = 7 = = = Permutation: an arrangement in which order is important wxyz is not the same as yxzw Apply the Fundamental Counting Principle to find how many permutations are possible using all 4 letters w, x, y, z with no repetition. 4 1st letter 3 2nd letter 2 3rd letter 1 = 4! = 24 possible arrangements 4th letter When you arrange n things, n! permutations are possible. Complete to find the number of permutations. 3. In how many ways can 6 people be 4. How many 5-digit numbers can be seated on a bench that seats 6? made using the digits 7, 4, 2, 1, 8 without repetitions? 6! =! = = possibilities = possibilities Apply the Fundamental Counting Principle to find how many permutations are possible using 4 letters 2 at a time, with no repetitions. 4 1st letter 3 = 12 possible 2-letter arrangements 2nd letter Apply the Fundamental Counting Principle. 5. In how many ways can 6 people be seated on a bench that seats 4? 1st seat 2nd seat 3rd seat 4th seat = possibilities 6. How many 3-digit numbers can be made using the digits 7, 4, 2, 1, 8 without repetitions? 1st digit 2nd digit 3rd digit = possibilities

Challenge Roundtable Discussion The number of ways in which 4 people can be seated in a row, on a bench that seats 4 is 4 P 4, or 4!. 4 1st seat 3 2nd seat 2 3rd seat 1 4th seat = 4! = 4 P 4 Now consider what happens if 4 people are seated in a circle, around a round table that seats 4. = 24 different arrangements Note that the 4 circular arrangements shown are really all the same with respect to who sits next to whom. For each of the 4! permutations, there are 4 alike. So, there are fewer ways to seat 4 people at a circular table that seats 4. 4P 4 4! 4 3 2 1 = = = 6 different arrangements 4 4 4 1. In how many different ways can 5 people be seated in a row, on a bench that seats 5? 2. In how many different ways can 5 people be seated in a circle, around a circular table that seats 5? 3. In how many different ways can n people be seated in a row, on a bench that seats n? Answer in factorial form. 4. In how many different ways can n people be seated in a circle, around a circular table that seats n? Answer in factorial form.

Problem Solving Permutations and Combinations Write the correct answer. 1. In a day camp, 6 children are picked to be team captains from the group of children numbered 1 through 49. How many possibilities are there for who could be the 6 captains? 2. If you had to match 6 players in the correct order for most popular outfielder from a pool of professional players numbered 1 through 49, how many possibilities are there? Volleyball tournaments often use pool play to determine which teams will play in the semi-final and championship games. The teams are divided into different pools, and each team must play every other team in the pool. The teams with the best record in pool play advance to the final games. 3. If 12 teams are divided into 2 pools, how many games will be played in each pool? 4. If 12 teams are divided into 3 pools, how many pool play games will be played in each pool? A word jumble game gives you a certain number of letters that you must make into a word. Choose the letter for the best answer. 5. How many possibilities are there for a jumble with 4 letters? A 4 C 24 B 12 D 30 7. How many possibilities are there for a jumble with 6 letters? A 120 B 500 C 720 D 1000 6. How many possibilities are there for a jumble with 5 letters? F 24 H 120 G 75 J 150 8. On the Internet, a site offers a program that will un-jumble letters and give you all of the possible words that can be made with those letters. However, the program will not allow you to enter more than 7 letters due to the amount of time it would take to analyze. How many more possibilities are there with 8 letters than with 7? F 5040 H 35,280 G 20,640 J 40,320 CODE Reading Strategies

Name Date Class Use a Visual Aid A permutation is an arrangement of objects in a certain order. How many different ways can you arrange these three shapes? You can use a tree diagram to visualize all of the possible arrangements: Use the tree diagram to answer the following. 1. If you start with the circle, how many different arrangements can you make? List them. 2. If you start with the square, how many different arrangements can you make? List them. 3. If you start with the triangle, how many different arrangements can you make? List them. 4. How many different arrangements can you make with these three shapes? CODE Puzzles, Twisters & Teasers

Finding a Treasure! Black out the incorrect expressions to see a shape. 9! = 362,880 2! = 4 11! = 9,497,876 3! = 9 5! = 120 5! = 25 3! = 6 4! = 14 2! = 2 10! = 100 6! = 150 5! = 125 8! = 40,320 7! = 49 6! = 36 4! = 256 7! = 5040 10! = 10,000,000 10! = 3,628,8000 7! = 823,543 4! = 24 9! = 729 12! = 144 8! = 16,777,216 11! = 39,916,800 What do you see?

LESSON 10-7 Practice A 1. 6 5 4 3 2 1 2. 3 2 1 3. 7 6 5 4 3 2 1 4. 8 7 6 5 4 3 2 1 5 4 3 2 1 5. 4 3 2 1 2 1 6. 9 8 7 6 5 4 3 2 1 6 5 4 3 2 1 7. 120 8. 362,880 9. 6 10. 40,320 11. 210 12. 8 13. 60 14. 4920 15. 6 16. 1 17. 3024 18. 42 19. 120 20. 720 21. 495 Practice B 1. 3,628,800 2. 6,227,020,800 3. 39,876,480 4. 478,638,720 5. 32,432,400 6. 13,366,080 7. 51,891,840 8. 19,535,040 9. 32,432,400 10. 336 11. 303,600 12. 1365 13. 792 14. 15,890,700 Practice C 1. 524,160 2. 2,441,880 3. 6188 4. 210 5. 3024 6. 1,814,400 7. 306 8. 36 9. 462 10. 78 11. 455 12. 15,504 groups 13. 720 schedules 14. 53,130 choices 15. 358,800 codes Review for Mastery 1. 4 3 2 1 ; 6 5; 210 4 3 2 1 2. 3; 6 5 4 3 2 1 ; 6 5 4; 120 3 2 1 3. 6 5 4 3 2 1; 720 4. 5; 5 4 3 2 1; 120 5. 6; 5; 4; 3; 360 6. 5; 4; 3; 60 7. 4; 6 2 ; 6 5 4 3 2 1 2 1 ; 360 8. 3; 3; 5 2 ; 5 4 3 2 1 ; 60 2 1 9. 4; 4; 2; 4; Challenge 3 6 1 5 4 3 2 1 2 1 4 3 2 1 ; 15 1. 5 P 5 = 5! = 5 4 3 2 1 = 120 5 2. P 5 5 = 5! 5 = 5 4 3 2 1 5 3. n! 4. (n 1)! Problem Solving 1. 13,983,816 possibilities 2. 10,068,347,520 possibilities 3. 15 games 4. 6 games 5. C 6. H 7. C 8. H Reading Strategies = 24 1. 2; circle, square, triangle; circle, triangle, square 2. 2; square, circle, triangle; square, triangle, circle, 3. 2; triangle, square, circle; triangle, circle, square 4. 6

Puzzles, Twisters & Teasers the shape of a large X